Plastics accumulator having first-in, first-out arrangement

ABSTRACT

Heat degradation of plastics is minimized using an accumulator in which fresh plastic is introduced into the accumulator at a point remote from the point where previously stored plastic is withdrawn. Consequently, plastic which was last introduced into this accumulator is withdrawn before freshly introduced plastic. A control system for regulating the flow of plastic is also disclosed.

United States Patent [191 Aker Sept. 10, 1974 1 PLASTICS ACCUMULATOR HAVING FIRST-IN, FIRST-OUT ARRANGEMENT [75] Inventor: James E. Aker, Seymour, 1nd.

[7 3] Assignee: Standard Oil Company, Chicago, Ill.

[22] Filed: Apr. 17, 1972 [21] Appl. No.: 244,976

Related U.S. Application Data [62] Division of Ser. No. 116,410, Feb. 18, 1971, Pat. No.

[52] U.S. Cl 222/1, 222/275, 222/385, 222/485, 222/487 [51] Int. Cl. G071 11/02 [58] Field of Search 222/137, 481, 482, 485,

[56] References Cited UNITED STATES PATENTS 2,106,620 1/1938 Nilson 222/378 X 2,174,319 9/1939 Gastraw 222/413 UX 2,597,175 5/1952 Perkins 222/137 2,616,130 11/1952 Banz 222/275 X 2,857,082 10/1958 Perkins 222/485 X 3,191,233 6/1965 Linderoth 222/413 UX 3,491,827 1/1970 Mace 164/318 FQREIGN PATENTS OR APPLICATlONS 607,592 9/1948 Great Britain 222/383 Primary Examiner-Robert B. Reeves Assistant Examiner-David A. Scherbel Attorney, Agent, or Firm-Robert B. Stevenson; Arthur G. Gilkes', William T. McClain [57] ABSTRACT Heat degradation of plastics is minimized using an accumulator in which fresh plastic is introduced into the accumulator at a point remote from the point where previously stored plastic is withdrawn. Consequently, plastic which was last introduced into this accumulator is withdrawn before freshly introduced plastic. A control system for regulating the flow of plastic is also disclosed.

6 Claims, 7 Drawing Figures PRESSURIZED GAS OIL-GAS CHAMBER PAIENIEUSEP 1 01914 SHEET- 1 0F 3 Qv NM omNEDmwumm PLASTICS ACCUMULATOR HAVING FIRST-IN, FIRST-OUT ARRANGEMENT CROSS-REFERENCES This application is a divisional application of US. Ser. No. 116,410 entitled AN IMPROVED ACCUMU- LATOR USEFUL IN MOLDING ARTICLES OF MANUFACTURE FROM PLASTIC, filed Feb. 18, 1971 in the name of James E. Aker now US. Pat. No. 3,707,248.

BACKGROUND In commercially available molding machines, extruded plastic flows through a fill line and manifold into an accumulator where it is stored before introduction into the mold. In typical accumulator/ manifold designs, a residual quantity of plastic remains in the accumulator even though the bulk of pre-stored plastic has been introduced into the mold. When the accumulator is refilled, this residual plastic remains at the top of the accumulator. And even with repeated discharges and refills this residual plastic remains trapped in the accumulator and gradually heat-degrades. Degradation results, for example, in color changes, and the discolored plastic must be discarded. (Light-colored molded articles are very difficult to produce without discoloration). Another problem encountered with conventional accumulator designs is the waste of plastic in changing the color of the molded articles. Many multicolored articles which are unacceptable are produced before unifonnity in color is attained. l have now invented an accumulator which alleviates these problems, and the drawings and accompanying description disclose the details thereof.

DESCRIPTION OF DRAWINGS FIG. 1 is a schematic view of a molding machine including the improved accumulator of my design.

FIG. 2 is an enlarged, cross-sectional view of my accumulator showing the accumulator being filled.

FIG. 3 is an enlarged, cross-sectional view of my accumulator showing plastic being discharged from the accumulator.

FIG. 4 is a cross-sectional view taken along line 4-4 of FIG. 1.

FIGS. 5(a) and 5(b) show, in partial view, an alternate embodiment of the accumulator.

FIG. 6 shows an alternate embodiment of my invention wherein a novel control system is used to regulate the flow of plastic.

PREFERRED EMBODIMENTS tion molding machine 12. Hot plastic from extruder 14.

flows through open safety valve 16 along conduit 18 through manifold 20 into accumulator 10. High pressure gas is introduced into extruder 14 at inlet 22 and is carried with the plastic into accumulator 10. When accumulator 10 has been filled with a shot of plastic, shut-off rods 24 are withdrawn from nozzles 26 in manifold 20. These rods 24 are connected to plate 28 which is moved to and fro by hydraulic cylinder 30. With the rods withdrawn from nozzles 26, as shown in FIG. 1, the shot from accumulator 10 is forced by piston 32 of a second hydraulic cylinder 34 through nozzles 26 and into mold 36. Simultaneously, the gas previously introduced into the hot plastic expands to provide a foamed article within mold 36. Introducing gas into the hot plastic is, however, an optional feature.

The chief components of my accumulator 10 are hollow, cylindrical chamber 40 having two open ends 42 and 44 and valve means 46. Piston 32 is seated in end 42 of chamber 40, is snug against the chambers sidewall 48 and is free to move along the longitudinal axis of chamber 40 in response to oil pressure in hydraulic cylinder 34. End 44 of chamber 40 serves as an orifice and this end has connected to it manifold 20 which feeds hot, fluid plastic into chamber 40. There is in end 52 of manifold 20 an enlarged cavity 50 which is adjacent end 44 of chamber 40 and has within it and attached to its sidewall perforated annular member 53 (FIG. 4). Cavity 50 also has open ends 54 and 56, with valve means 46 moving between ends 54 and 56.

Valve means 46, as best shown in FIGS. 2 and 3, includes bulbous member 60 which is within enlarged cavity 50 and free to move to and fro in cavity 50. However, the bulbous members movement is restricted at end 54 by cavity wall 62 and at end 56 by perforated annular member 53. Bulbous member 60 includes an opening 51 and extending therethrough is elongated tubular member 64 which serves as a passageway for fluid plastic. This tubular member 64 is free to move relative to member 60 and it has terminus 66 remote from the orifice of chamber end 44 and terminus 68 within cavity 50. At terminus 66 is head 70 having a female portion 72 which matches a male portion 74 of piston 32. Male portion 74 has an extended conical piece 76 which is adapted to fit into female portion 72 of tubular member 64.

FIG. 2 shows plastic flowing from extruder 14 into chamber 40. This plastic pushes against bulbous mem-' ber 60, forcing this member to close ofi end 54 of cavity 50 by blocking the orifice leading into chamber 40. However, plastic will flow through tubular member 64, push against piston 32 and flow around head 70. The pressure in hydraulic cylinder 34 is, less than that of the plastic, thus piston 32 will move away from female portion 72 providing gap 73 which permits the fluid plastic to flow into chamber 40. By filling chamber 40 at a point remote from the orifice of end 44, previously stored plastic is pushed toward the orifice and will be the first to leave accumulator 10 when the shot" is introduced into mold 30.

FIG. 3 portrays the shot beingintroduced into member 53. Plastic within tubular member 64 also flows from terminus 68. Thus previously stored plastic will always leave chamber 40 before freshly introduced plastic. This minimizes the dwell time of the plastic within chamber 40 and reduces, dramatically, the possibility of heat degradation of the plastic and multicolored article rejects.

FIGS. 5(a) and 5(b) show a one-piece design wherein piston 32 is connected to terminus 66 of tubular member 64. In this design terminus 66 includes connector members 69 which are integral with piston 32. There are passageways between these connector members 69 which provide a spider-like channel arrangement permitting plastic to flow from tubular member 64 into chamber 40. Since this design does not close off flow as does the design illustrated in FIGS. 3 and 4, some back-flow occurs through member 64 when plastic is expulsed from accumulator 10. However, the crosssectioned area for flow within member 64 is about 1 that provided by cavity 50, minimizing the back-flow.

FIG. 6 shows an alternate embodiment of my invention including a novel control system. Parts identical with those shown in FIGS. 1-4 are identified with the same numerals. The only significant difference between the apparatus shown in FIGS. 1-4 and that shown in FIG. 6 is the use of temperature-, pressurecompensated flow control valve 100 in place of block valve 75, and hydraulic cylinders 101-106 with associated temperature, pressure-compensated flow control valves l0la-106a, respectively, in place of block 28 and hydraulic cylinder 30. Each rod 24 also has a stop 24a which limits the movement of the rod. Suitable temperature-, pressure-compensated flow control valves may be purchased from Vickers Industrial Hydraulics Division of Sperry-Rand (valve No. FCG- 1500).

My novel control system provides flexible control for the feeding of plastic to mold 36 independent of the flow properties of the plastic or other characteristics of the plastic. Temperature-, pressure-compensated flow control valve 100 provides a controllable and reproducible oil flow rate to hydraulic cylinder 34. Consequently, accumulator 10 empties stored plastic at a rate independent of the plastic flow properties. Since hydraulic cylinders 101-Qcan independently move rods 24 relative to each other, controlled flow of the plastic into mold 36 is possible. By placing temperature-, pressure-compensated flow control valves 101a-l06a in the oil line to hydraulic cylinders 101-106, a controllable and reproducible rate of shut-off rod withdrawal and insertion into nozzles 26 is possible. By adjusting the oil flow rates to cylinders 101-106, plastic flow through any given nozzle can be adjusted to occur over a given portion of the accumulator stroking period.

The prior art system typically includes a flow control valve machined into the manifold upstream of each nozzle, providing a variable restriction. Flow through such valves has been found to be significantly affected by lot to lot changes in the plastic, temperature fluctuation within the manifold/nozzle system,and variations of the extruder feed. Such valves also introduce dead areas and are difficult to adjust and subject to fouling. My flow control system eliminates dead areas and allows greater flexibility of plastic flow. Moreover, the temperature, pressure-compensated flow control valves used in my system may be mounted in a readily accessible location regardless of the design of the apparatus.

I claim:

1. In an apparatus wherein hot, fluid plastic is introduced into. stored in and periodically withdrawn from an accumulator through the same orifice. internal means for introducing fresh plastic into the accumulator at a point remote from the point where stored plastic is withdrawn so that plastic which was first introduced into the accumulator is withdrawn before the freshly introduced plastic.

2. In a process wherein hot, fluid plastic is introduced into, stored in and periodically withdrawn from an accumulator through the same orifice, the step of introducing fresh plastic into the accumulator at a point remote from the point where stored plastic is withdrawn so that plastic which was first introduced into the acetimulator is withdrawn before the freshly introduced plastic.

3. In combination, supply means for plastic, accumulator means for receiving and storing plastic from said supply means, manifold means connecting the supply means and the accumulator means, said manifold means including a plurality of nozzles, shut-off rod means for the nozzles movable between positions which permit in one position and prevent in another position flow of plastic through said nozzles, and conduit means through the manifold placing the supply means and accumulator means in communication with each other, and control means including cylinder means connected to each of said shutoff rod means and temperature, pressure-compensated flow control valve means for each of said cylinders which control the flow of pressurizing fluid to said cylinders.

4. The combination of claim 3 wherein the accumulator means includes cylinder means and temperature-, pressure-compensated flow control valve means for said accumulator cylinder means which controls the flow of pressurizing fluid to said cylinder means.

5. The combination of claim 4 wherein the accumulator means includes a chamber including an orifice in communication with said manifold means through which plastic may flow and a valve means at said orifice which, in response to plastic being forced from the chamber, moves to a first position permitting plastic to flow from the chamber through the orifice and, in response to fluid attempting to enter the chamber through orifice, moves to a second position preventing fluid from flowing directly into the chamber through said orifice, said valve means characterized in that it includes an elongated passageway into the chamber having a terminous remote from said orifice, said passageway permitting plastic to enter the chamber at av point remote from said orifice when the valve means is in the second position.

6. The combination of claim 4 wherein the accumulator means adapted to store fluid plastic or the like comprises: a hollow, cylindrical chamber having first and second ends and an inner sidewall; a piston at the chambers first and seated in the chamber so that it is snug against the chambers inner sidewall, said piston being movable along the longitudinal axis of the chamber in both forward and reverse directions; means coupled to the chambers second end and in communication with said plastic or the like, said communicating means having therein, adjacent chambers second end, an enlarged cavity which has first and second open S 6 ends and a perforated stop member at the cavitys sectys second end and engaging said stop member, ond end, and a valve at the chambers second end ind Cludmg b. an elongated tubular member extending through a. a bulbous member within the cavity, but smaller Said bulbous member, Said tubu'ar member having than said cavity so that said bulbous member is free to move within the cavity in response to flowing plastic, said bulbous member, as the plastic flows toward the chamber, moving to a position blocking a first terminus near the chambers first end and a second terminus near the cavitys second end, said tubular member allowing plastic to flow therethe cavitys first end and preventing plastic from through (either into or from the chamber regardless I flowing directly into the chamber and, as plastic 10 Of the P t o 0 the bulbous member. flows from the chamber, moving toward the cavi- 

1. In an apparatus wherein hot, fluid plastic is introduced into, stored in and periodically withdrawn from an accumulator through the same orifice, internal means for introducing fresh plastic into the accumulator at a point remote from the point where stored plastic is withdrawn so that plastic which was first introduced into the accumulator is withdrawn before the freshly introduced plastic.
 2. In a process wherein hot, fluid plastic is introduced into, stored in and periodically withdrawn from an accumulator through the same orifice, the step of introducing fresh plastic into the accumulator at a point remote from the point where stored plastic is withdrawn so that plastic which was first introduced into the accumulatoR is withdrawn before the freshly introduced plastic.
 3. In combination, supply means for plastic, accumulator means for receiving and storing plastic from said supply means, manifold means connecting the supply means and the accumulator means, said manifold means including a plurality of nozzles, shut-off rod means for the nozzles movable between positions which permit in one position and prevent in another position flow of plastic through said nozzles, and conduit means through the manifold placing the supply means and accumulator means in communication with each other, and control means including cylinder means connected to each of said shut-off rod means and temperature-, pressure-compensated flow control valve means for each of said cylinders which control the flow of pressurizing fluid to said cylinders.
 4. The combination of claim 3 wherein the accumulator means includes cylinder means and temperature-, pressure-compensated flow control valve means for said accumulator cylinder means which controls the flow of pressurizing fluid to said cylinder means.
 5. The combination of claim 4 wherein the accumulator means includes a chamber including an orifice in communication with said manifold means through which plastic may flow and a valve means at said orifice which, in response to plastic being forced from the chamber, moves to a first position permitting plastic to flow from the chamber through the orifice and, in response to fluid attempting to enter the chamber through orifice, moves to a second position preventing fluid from flowing directly into the chamber through said orifice, said valve means characterized in that it includes an elongated passageway into the chamber having a terminous remote from said orifice, said passageway permitting plastic to enter the chamber at a point remote from said orifice when the valve means is in the second position.
 6. The combination of claim 4 wherein the accumulator means adapted to store fluid plastic or the like comprises: a hollow, cylindrical chamber having first and second ends and an inner sidewall; a piston at the chamber''s first and seated in the chamber so that it is snug against the chamber''s inner sidewall, said piston being movable along the longitudinal axis of the chamber in both forward and reverse directions; means coupled to the chamber''s second end and in communication with said plastic or the like, said communicating means having therein, adjacent chamber''s second end, an enlarged cavity which has first and second open ends and a perforated stop member at the cavity''s second end, and a valve at the chamber''s second end including a. a bulbous member within the cavity, but smaller than said cavity so that said bulbous member is free to move within the cavity in response to flowing plastic, said bulbous member, as the plastic flows toward the chamber, moving to a position blocking the cavity''s first end and preventing plastic from flowing directly into the chamber and, as plastic flows from the chamber, moving toward the cavity''s second end and engaging said stop member, and b. an elongated tubular member extending through said bulbous member, said tubular member having a first terminus near the chamber''s first end and a second terminus near the cavity''s second end, said tubular member allowing plastic to flow therethrough either into or from the chamber regardless of the position of the bulbous member. 